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Machine Learning Without a Processor: Emergent Learning in a Nonlinear Electronic Metamaterial

Soft Condensed Matter 2024-07-10 v2 Emerging Technologies Machine Learning

Abstract

Standard deep learning algorithms require differentiating large nonlinear networks, a process that is slow and power-hungry. Electronic learning metamaterials offer potentially fast, efficient, and fault-tolerant hardware for analog machine learning, but existing implementations are linear, severely limiting their capabilities. These systems differ significantly from artificial neural networks as well as the brain, so the feasibility and utility of incorporating nonlinear elements have not been explored. Here we introduce a nonlinear learning metamaterial -- an analog electronic network made of self-adjusting nonlinear resistive elements based on transistors. We demonstrate that the system learns tasks unachievable in linear systems, including XOR and nonlinear regression, without a computer. We find our nonlinear learning metamaterial reduces modes of training error in order (mean, slope, curvature), similar to spectral bias in artificial neural networks. The circuitry is robust to damage, retrainable in seconds, and performs learned tasks in microseconds while dissipating only picojoules of energy across each transistor. This suggests enormous potential for fast, low-power computing in edge systems like sensors, robotic controllers, and medical devices, as well as manufacturability at scale for performing and studying emergent learning.

Keywords

Cite

@article{arxiv.2311.00537,
  title  = {Machine Learning Without a Processor: Emergent Learning in a Nonlinear Electronic Metamaterial},
  author = {Sam Dillavou and Benjamin D Beyer and Menachem Stern and Andrea J Liu and Marc Z Miskin and Douglas J Durian},
  journal= {arXiv preprint arXiv:2311.00537},
  year   = {2024}
}

Comments

11 pages 8 figures

R2 v1 2026-06-28T13:08:35.869Z